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. Combining field-level data with other data available in the cloud, such as weather data and food pricing models allow to further optimize smart farming. Among the most impactful operations for sustainable
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thin films. Technical difficulties remain however for the realization of optimal epitaxial layers, in accordance with this new approach and able to withstand a voltage of 1400 V. The proposed thesis will
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Centre de Mise en Forme des Matériaux (CEMEF) | Sophia Antipolis, Provence Alpes Cote d Azur | France | about 2 months ago
of these microstructures, influenced by the nature of the materials and the welding parameters, is a major challenge for the future optimization of NDT methods. In this context, this PhD project aims to develop virtual
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of dye-producing bacteria and the characterization of their pigments, through the optimization of their production and application, to the comprehensive ecological and economic evaluation of the resulting
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compatible with high-speed imaging over long durations, (2) optimize system control and develop signal processing tools, and (3) apply it to imaging challenges involving organoids and living biological tissues
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and optimization with a focus on the design of a robust reusable first stage with respect to model hypotheses (emissions, LCA) and uncertainties. Research Objectives: Development of a multidisciplinary
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of chemical compounds (NMR, GC-MS, IR, X-Ray). The student will also have access to modern optimization methods for catalytic systems, such as highthrouput experimentation (HTE, collaboration with the HTE
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-dimensional plasmonic metasurfaces. The goal is to disentangle hot-carrier and thermal contributions and optimize metasurface designs for site-selective hot-carrier generation with minimal heating. The work
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system. To achieve this, the PhD will combine: instrumental development (optical optimization, illumination strategies, multi-camera synchronization), optical modeling (contrast mechanisms in phase
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methodology toward 3D spatial and temporal strain–temperature imaging for the optimization of next-generation electronic and optoelectronic devices. Further information may be obtained from: Tobias Schülli (tel